FR3140894A1 - Insulating plant module for walls and roofs of buildings - Google Patents

Abstract

PLANT MODULE FOR BUILDING WALLS AND ROOFS Plant module (100, 200, 300, 400, 700, 800) to cover all or part of building facades or roofs, installed indoors or outdoors, comprising a structure (10 , 20, 30, 40, 70, 80), comprising walls (106a-e, 206a-g, 306a-e, 406a-e, 706a-e, 806a-f) forming a semi-open support for containing a substrate (16, 26, 36, 46, 76, 86), and comprising a rear wall (106b, 206b, 206d, 306e, 406b, 706b, 806b) for fixing, said module comprises at least one permanent magnet (104, 204, 304, 404, 704, 804), to fix said rear wall on a support surface. Abstract figure: figure 1

Description

Insulating plant module for walls and roofs of buildings

The present invention belongs to the field of construction and renovation of buildings.

The present invention relates more particularly to a plant module for walls and roofs making it possible to green the various facades of buildings and finds direct application in the insulation and protection of facades made of concrete, wood or having metal cladding.

State of the art

In the field of building construction, improving their energy performance in order to save energy and provide more comfort to users is one of the subjects that has experienced strong development in recent years.

In the first part of the ^20th century, it was not uncommon to construct buildings with little thermal insulation. In fact, the heating methods of the time made it possible to compensate for ineffective thermal insulation during the cold seasons.

The first oil shock of the 1970s had the consequence, among other things, of changing certain habits in construction, in particular by beginning to integrate the notion of insulation of facades and roofs, with the aim of improving user comfort and achieving at the same time energy savings.

The mid-1970s also saw strengthened legislation in the field of construction in France, requiring thermal insulation of new buildings.

From the 1980s, in order to encourage and encourage individuals as well as companies to thermally insulate their buildings, and by going beyond the regulations, different labels emerged to reward building stakeholders.

During the end of the ^20th century, regulations on the thermal insulation of buildings were strengthened.

At this same period, the international community became aware of the need to control greenhouse gas emissions from industrialized and developing countries, in particular through the organization of the first Conferences of the Parties (in English Conference of the Parties , COP ) and the signing in 1997 of the Kyoto Protocol.

Subsequently, different thermal regulations (RT) in France emerged and made it possible to define new objectives in terms of insulation (level of performance, etc.).

Recently, France moved from RT 2012 thermal regulations to environmental regulations (RE 2020), which are more ambitious, demanding and restrictive for the construction sector.

In parallel with these regulatory developments, innovative solutions are emerging.

Historically, the energy efficiency of homes could be improved through interior thermal insulation (ITI), for example by adding insulating materials to the walls of certain rooms. If in certain cases this type of renovation is suitable, for other homes and buildings, it is very restrictive to implement.

This is how external thermal insulation (ITE) is developing, allowing, like internal thermal insulation, to improve thermal comfort, both in the winter and summer seasons, while remaining economical. .

In parallel with external thermal insulation, the greening of facades and roofs is a technique which is becoming more and more widespread, and is a serious avenue for increasing the energy efficiency of buildings, while replanting plants which will promote biodiversity in these new spaces.

• fixer sur la face extérieure de la façade à traiter d'un bâtiment, un ensemble de panneaux ;
• disposer par projection sur ces panneaux assemblés un enduit.

Document EP2052116 presents a process for thermal insulation of the facade of a building comprising steps which consist of:

• fix on the exterior face of the facade to be treated of a building, a set of panels;
• spray a coating onto these assembled panels.

As a general rule, insulation panels are fixed to the load-bearing walls of buildings using insulation dowels which allow the insulation to be maintained. The wall can also be previously covered with glue to strengthen the hold of the panels. As the panels are made of expanded polystyrene, a permeable material, a finishing step consisting of covering the panels with a coating or wooden cladding for example, is to be expected.

Therefore, using this type of solution requires first drilling the walls which will receive the insulation panels, then preparing the surfaces for gluing the insulation panels, and covering them.

This type of installation, which mainly only includes a thermal solution, can be long and expensive depending in particular on the surface area to be covered. In addition, this solution is not suitable for metal facades.

Document FR2952079A1 presents a screen formed of boxes which are held on a vertical surface by means of hooks placed on through rails, smooth which are themselves fixed beforehand on the vertical surface. Assembled, these boxes make it possible, for example, to construct screens which have only one decorated side. Depending on the composition of the screens, they can be used in particular to thermally insulate buildings from the outside but also to green them by integrating plants into the boxes. As mentioned in the previous document, the installation of the solution described here requires drilling the surface on which supports will then be placed which will be used to hold boxes, the contents of which will eventually be used to insulate the facades.

Thus, and to the knowledge of the applicant, there are no external thermal insulation solutions, nor greening modules, suitable for facades comprising metal cladding, without prior drilling work and self-supporting. There are also no ITE solutions for concrete supports and wooden cladding with integrated greening.

Therefore, and in order to facilitate external thermal insulation projects and the maintenance of green walls, new solutions must be developed.

Presentation of the invention

The present invention aims to overcome all or part of the disadvantages mentioned above.

For this purpose, the present invention aims at a plant module for covering all or part of building facades or roofs, installed indoors or outdoors, said module comprising a structure, comprising walls forming a semi-open support for containing a substrate, and comprising a rear fixing wall. This plant module is remarkable in that it comprises at least one permanent magnet, for fixing said rear wall to a support surface, the force of attraction and the force of adhesion exerted on the support surface being sufficiently high to guarantee the maintaining said module in place. This characteristic has the particular advantage of being able to fix and move the plant module on metal facades of buildings, without requiring drilling into said facades.

According to a particular characteristic, the plant module the permanent magnet has a substantially cylindrical shape, and preferably has a passage allowing said magnet to be screwed to the rear wall of the structure, or to a support surface. Thus, it is possible to use the plant module on surfaces that are not magnetizable, or to position magnets on plant modules.

According to another particular characteristic, the permanent magnet, used with the plant module, is covered with a waterproof rubber coating. The permanent magnet is then protected from bad weather and humidity. This property then allows outdoor use and also prevents the effect of corrosion, due to the oxidation of the permanent magnet, on the metal surfaces where the plant module is fixed. Also, the rubber coating protects against breakages and impacts. Furthermore, friction is increased by the use of magnets with this type of coating. Finally, the handling of these magnets is facilitated, not scratching the surfaces on which they are positioned.

Advantageously, the plant module comprises a drip watering pipe which is held in notches positioned on side walls of said module, said watering pipe being provided with a quick coupling system at each of its ends to connect said garden hose to the garden hose of a neighboring module. These notches make it easier to hold the drip pipes in place and limit their potential movements in the modules. In addition, the quick connection of the drip pipes allows you to easily install, move or reposition a plant module as presented.

According to a particular embodiment, the structure of the plant module is made of galvanized steel.

According to another particular embodiment, the structure of the plant module is made of extruded polystyrene, and the at least one permanent magnet is screwed onto the rear wall of the structure of said module. Thus, thermal insulation is then included in the structure of the plant module.

According to another particular embodiment, the plant module comprises at least one thermal insulating plate preferably made of biosourced material, and being arranged between the substrate and the rear wall of the structure, and/or on a surface to be vegetated of said substrate. . Thus, thermal insulation is fully configurable and adaptable to the needs of the building.

Advantageously, the plant module comprises a first thermal insulating plate, in contact with the rear wall, which is followed by a second rigid thermal insulating plate, juxtaposed with a vapor barrier film, in contact with the substrate, and a third thermal insulating plate. Again, the content of the plant module is fully configurable, adaptable and customizable to the surfaces on which said module is installed, as well as to the plants planted in said module. In addition, the thermal insulation used in the plant module also plays an acoustic insulation role. The plant module then makes it possible, in addition to thermally insulating a building, to insulate it acoustically.

Advantageously, the front wall of the plant module comprises at least one orifice for placing at least one plant plant. In addition, the front wall may include a plurality of orifices of different shapes. Thus, the integration of plant plants is facilitated and is not constrained by standardized dimensions of the orifices.

Advantageously, the plant module comprises at least one drain hole arranged on a bottom of the structure to evacuate excess water present in the substrate. The irrigation of the plant modules is controlled and promotes the growth of plant plants.

According to a particular embodiment, the rear wall of the plant module comprises at least one orifice allowing air circulation. In addition, air entering and leaving the building can be forced to circulate through the substrate by means of a sealed frame preventing air from passing over the edges of the plant modules.

According to another embodiment, the plant module is intended to cover a roof in a substantially horizontal position, the structure of said module comprising at least one flow channel on the rear wall of said module, said channel draining the excess water present in the substrate.

According to a particular embodiment of the plant module, its structure has an angle α, the value of which corresponds to that of building corners. Advantageously, this characteristic makes it possible to position the plant module in the corners of the building and then makes it possible to maximize the plant cover of the facades of the latter. The angle α is approximately 90° in the majority of cases, without this presenting a limit to the invention.

Advantageously, the structure of the plant module includes an anti-shock coating.

According to another embodiment of the plant module whose structure is made of extruded polystyrene, said structure comprises at least one hanging support on which at least two permanent magnets are magnetically fixed.

According to another embodiment, the plant module is intended to be placed on a ground, and its structure serves as a support for a module located above said module.

Finally, the present invention also relates to a building, covered at least partially with a set of plant modules as presented.

The fundamental concepts of the invention having just been explained above in their most basic form, other details and characteristics will emerge more clearly on reading the description which follows and with reference to the appended drawings.

Presentation of the drawings

The figures are given for purely illustrative purposes for a better understanding of the invention without limiting its scope. The different elements can be represented schematically and are not necessarily on the same scale. In all the figures, identical or equivalent elements bear the same numerical reference.

It is thus illustrated in:

: an exploded perspective view of a plant module according to a first embodiment of the invention;

: a perspective view of a plant module according to a second embodiment;

: a perspective view of a structure of the first embodiment of the plant module;

: a perspective view of a structure of the second embodiment of the plant module;

: a perspective view of a structure according to a variant of the first embodiment of the plant module;

: a perspective view of a structure according to another variant of the first embodiment of the plant module;

: a perspective view of the stages of an assembly of a third embodiment;

: a perspective view of the third embodiment of the plant module;

: another perspective view of the third embodiment of the plant module;

: a perspective view of a building on which plant modules are installed;

: a side view of the installation of two plant modules on metal cladding;

: a perspective view of a plant module according to a fourth embodiment;

: a perspective view of a structure of the fourth embodiment of the plant module;

: an exploded and perspective view of a plant module according to a fifth embodiment;

: a perspective view of the fifth embodiment of the plant module;

: a perspective view of a sixth embodiment serving as a support module;

: a perspective view of an arrangement between two plant modules, one of which is positioned on the support module.

Detailed description of embodiments

It should be noted that certain technical elements well known to those skilled in the art are described here to avoid any insufficiency or ambiguity in the understanding of the present invention.

In the embodiment described below, reference is made to a plant module for facades and roofs of buildings comprising various elements stabilizing vegetation and providing additional external thermal and sound insulation to buildings, said module being installed in particular on metal cladding using permanent magnets.

There represents an exploded and perspective view of a particular embodiment of a plant module 100 mainly comprising a structure 10 of parallelepiped shape, preferably made of galvanized steel, which is an entirely recyclable material, and which moreover effectively protects the cladding of bad weather and shocks, thus extending its lifespan.

The structure 10 comprises five walls 106a-e, including a front wall 106a on which is present at least one orifice 107, said structure comprising a first thermal insulating plate 12 preferably made of recycled textile fiber, a second thermal insulating plate 13 preferably made of biosourced cork, comprising at least one orifice 131, at least one flexible mesh 14, a vapor barrier film 15 comprising at least one orifice 151, a substrate 16, a third thermal insulating plate 17 preferably made of hemp or recycled geotextile and plant plants 18.

The plant plants 18, once positioned in the orifices 107 or previously cultivated, pass through the thermal insulating plate 17 made of hemp or recycled geotextile at the level of orifices created manually during the passage of the plants, subsequently retaining the substrate 16, then are planted individually in said substrate, which has the property of being very light and airy in order to facilitate the circulation of air inside.

The front wall 106a corresponds to the wall located on the side of the plant plants 18 and a rear wall 106b of the structure 10 corresponds to the wall opposite the wall on which said plants are installed.

The substrate 16 is irrigated by means of a drip watering pipe 103, resting on an edge 161 of said substrate, watering pipe 103 in which the water circulates and passes through small diameter orifices (not represented here), thus ensuring slow and diffuse irrigation at the level of the substrate 16 and also limiting excess watering.

The drip watering pipe 103 is held at the level of the structure 10 by being inserted into two notches 101, located on walls 106c and 106d of said structure, the walls 106c and 106d being themselves located on either side and d 'other of wall 106a.

At the ends 118 and 119 of the drip watering pipe 103 there is a system of connections (not shown here) such as by screwing, by clipping, by insertion, making it possible to assemble the watering pipes in a watertight and rapid manner. plant modules between them.

The irrigation system of the plant module 100 is composed of a multitude of drip irrigation pipes 103 connected together, said pipes being connected to a public water distribution network or to a borehole. It is also possible to pump the rainwater retention basins located nearby, and when the level is sufficient, thus allowing better water management. Fish can be raised in these ponds to combat the appearance of mosquitoes and, through bacteria, to create water rich in minerals, notably containing nitrates and phosphates, thus contributing to a supply of natural fertilizer. efficient and an ecosystem conducive to the development of plant plants 18, thanks to the principle of aquaponics. Furthermore, the plant modules 100 are irrigated by means of a pump (not shown here) whose watering flow rate is adjustable and controllable according to the hours and days of the week.

In addition to the drip watering pipe 103, a gutter 102 is present on the front wall 106 of the structure 10 and makes it possible to capture the rainwater which runs off the surfaces in order to once again optimize the use of water.

In order to maintain the structure 10 on a metal cladding, four permanent magnets 104 distributed on the rear wall 106b of said structure are used. These permanent magnets 104 can be screwed onto the rear wall 106b by means of screws inserting into passages 105, or simply magnetized onto said wall, which as a reminder is preferably made of galvanized steel. Permanent magnets 104 can be covered with a rubber coating (strip, disk, cap) in order to increase their shear force and adhesion.

Furthermore, the rubber coating of the permanent magnet 104 has the function of making it waterproof as well as moisture-proof. This property then allows outdoor use and also prevents the effect of corrosion, due to the oxidation of the permanent magnet 104, on the metal cladding where the plant module 100 is positioned.

The elements which are housed in the structure 10 are maintained inside said structure because the latter has a bottom 106e on which the first thermal insulating plate 12 made of recycled textile fiber is placed, the second plate of rigid thermal insulation 13 in biosourced cork, the substrate 16 and the third thermal insulating plate 17 in hemp or recycled geotextile. The vapor film 15 is for its part inserted between the second rigid thermal insulation plate 13 made of cork and the substrate 16 in order to protect said plate from the humidity present in the substrate 16. In addition, the flexible mesh 14, positioned between the vapor barrier film 15 and the second rigid thermal insulation plate 13 made of cork, prevents the substrate 16 from spreading through the orifices 151 and 131.

Thus, when a thermal insulator is positioned inside the structure 10 of the plant module 100, said module can be used to thermally insulate from the outside, one or more building facades.

In addition, the plant modules 100 being held in place by means of permanent magnets 104, said modules can be moved on the same facade and interchangeable. Several species of plant plants 18 can be planted in plant modules 100, thus creating real vertical gardens on the facades of buildings, gardens conducive to the development of biodiversity around said buildings and the effects of decarbonization.

Finally, the structure 10 of the plant module 100 can, in its simplest configuration, include only the substrate 16 as well as the plant plants 18, in addition to the drip watering pipe 103 and the permanent magnets 104. In this configuration, no thermal insulation is therefore used.

Advantageously, the plant module 100 makes it possible to adapt for each installation the number as well as the type of insulators to be positioned in the structure 10, depending on the need for thermal insulation (for example, buildings made up of partial insulation) , thus allowing other embodiments.

There represents a perspective view from above of a plant module 200 according to a second embodiment, which adapts to the corners of building facades.

In this embodiment, the shape of which differs from the plant module 100 represented in , the plant module 200 comprises a structure 20, in which are positioned a substrate 26, a thermal insulating plate 27, preferably made of hemp, plant plants 28, said structure also comprising a gutter 202 and notches 201 serving to maintain a 203 drip garden hose.

The drip watering pipe 203 has the function of transporting the water which irrigates plant plants 28, as previously. The drip watering hose 203 has at these two ends 218 and 219 a system of quick connectors (by screwing, by clipping, by insertion, etc.).

There represents a perspective view of the structure 10 of the empty plant module 100. As mentioned above, the structure 10 of the plant module 100 is parallelepiped in shape and has five walls 106a-e. The structure 10 has the dimensional characteristics of a length L10, a height H10 and a depth P10. Preferably, the length L10 as well as the height H10 are equal to 500 mm, and the depth P10 is equal to 200 mm. In addition, the thickness of the galvanized steel used to manufacture structure 10 is equal to 1 mm. These dimensional values are given as an example, and do not present a limit, the person skilled in the art can define others depending on the needs and the buildings on which the plant module 100 is installed.

The front wall 106a comprises at least one orifice 107, preferably circular in shape, making it possible to position a plant 18 or to carry out cultivation. In this example, the front wall 106a has sixteen orifices 107 having a diameter D107 of 80 mm. The diameter D107 as well as the position of the orifices 107 are not limiting characteristics of the invention. Indeed, the orifices 107 can also be of polygonal shapes (hexagon, rectangle, triangle, etc.). In addition, the front wall 106a may include several orifices 107 of different sizes and shapes.

In order to prevent water from stagnating, the bottom 106e of the structure 10 includes at least one drain hole 110, thus making it possible to drain excess water at the level of the plant module 100.

The rear wall 106b comprises at least one orifice 112 allowing a gas exchange between the air located inside and outside a building, passing through the plant module 100, both by suction and by extraction. Preferably, the orifice 112 has a diameter varying from 20 mm to 200 mm. Thus, by passing through the roots of the plant plants 18, the air is filtered. Indeed, one of the advantages of the plant module 100 is to allow, in addition to the capture by the foliage of carbon dioxide (CO2) released by buildings and present in the air, to also sequester the CO2 by the root tissue of the plants. plant plants 18.

This solution allows decarbonization and limits the environmental impact of buildings by reducing their greenhouse gas emissions, natural sequestration being adapted to this type of emission sources considered to be diffuse.

There represents a perspective view of the structure 20 of the empty plant module 200. As a reminder, the design of structure 20 allows it to be positioned in the corners of building facades in order to maximize their plant cover in particular.

The structure 20 has seven walls 106a-g, and has a height H20 preferably equal to 500 mm.

The “L” or “V” shape of the structure 20 is produced by assembling a first front wall 206a of length L206a, a second front wall 206c of length L206c, a first wall rear wall 206b of length L206b and a second rear wall 206d of length L206d.

The front wall 206a and the rear wall 206b are parallel. It is the same for the front wall 206c and the rear wall 206d.

An angle α , of value equal to 90° in this example, allows the structure to be positioned in a corner. The value of the angle α can vary in order to adapt to different corners of buildings.

Furthermore, in the embodiment of the structure 20 shown in , called “V” shaped, the lengths L206a and L206c of the front walls 206a and 206c are equal, and the lengths L206b and L206d of the rear walls 206b and 206d are also equal.

For other embodiments of the structure 20, called "L" shaped, the lengths L206a and L206c of the front walls 206a and 206c may be different, also generating a difference between the lengths L206b and L206d of the rear walls 206b and 206d.

In order to fix the plant module 200 on a support, permanent magnets 204 are positioned at the rear walls 206b and 206d. As before, these permanent magnets 204 have a passage 205 in order to be able to screw them, and said magnets can be covered with a rubber coating.

Advantageously, these variations in the dimensional characteristics of the structure 20 (angle α , lengths, L206a-d) make it possible to adapt the plant module 200 to all the corners of buildings.

As previously, the structure 20 includes a bottom 206g which includes at least one drain hole 210 making it possible to drain excess water at the level of the plant module 200.

There and the respectively represent a structure 60a and a structure 60b according to other embodiments of the plant module 100.

These figures illustrate design possibilities different from those shown in Figures 1 to 4.

In these two embodiments, the structure 60a and the structure 60b each comprise eight orifices 607a and 607b respectively, arranged either vertically or horizontally.

Thus, the structure 60a has a length L60a, and the structure 60b, a height H60b, which each differ from the dimensions of the length L10 and the height H10 of the structure 10.

Advantageously, these different designs make it possible to adapt more easily to the facades of the buildings where these structures are installed.

There represents a perspective view of steps (a) to (e) of an assembly of a plant module 300, according to another embodiment, which is used to green the roof of a building comprising steel tray sheets.

A first step a represents a structure 30 of the plant module 300 for roofing. The structure, preferably made of fully recyclable galvanized steel, has five walls 306a-e, and has as main dimensional characteristics a length L30, a width l30 and a height H30.

In this example, the plant module 300 includes four permanent magnets 304, making it possible to maintain the structure 30 on the roof of a steel tank type building. Each of the permanent magnets 304 has a passage 305 for screwing said magnets to the structure 30 or to a building if necessary.

The structure 30 also comprises at least one flow channel 302, of the same length L30 as said structure, of width l302 and depth p302. The rainwater, or the water used to irrigate the module 300, is then recovered in the flow channel 302 to prevent it from stagnating.

A second step b represents the addition of a water retention mat 37, preferably biosourced, making it possible to optimize water requirements.

In a third step c , a substrate 36 is added on top of the water retention mat 37.

During a fourth step d , at least one drip watering pipe 303, comprising small diameter orifices (not shown here), is placed on the substrate 36 in order to irrigate the module 300. Maintaining the pipe 303 drip dripping at the level of the structure 30 is carried out by means of notches 301.

In order to assemble watertight and quickly the drip irrigation pipes 303, they have a system of fittings at their ends 318 and 319.

Finally, a fifth step consists of adding a carpet of plants 38 of your choice, depending on the locality, to cover everything. It is possible to maintain all the elements, the water retention mat 37, the substrate 36 as well as the plant mat 38, to the structure 30, and the walls 306a-d make it possible to avoid being caught in the wind. of these elements.

In other embodiments, a frame system is applied around the entire perimeter of the structure 30 in order to avoid being caught in the wind.

In other embodiments, the plant module 300 may comprise at least one layer of thermal insulation, as presented in . The height H30 of the plant module 300 is then a function of the different layers (water retention mat 37, substrate 30, insulation, etc.) which are integrated into said module.

Figures 7A and 7B represent the plant module 300 in perspective, respectively in front top view and in rear top view.

On the , it is possible to see on the wall 306d of the structure 30, an extension 302d of the flow channel 302. The extension 302d is inserted at the level of an opening 302c, visible on the , of the flow channel 302 of an adjacent plant module 300.

This interlocking allows partial covering of the channels 302 of two plant modules 300 juxtaposed longitudinally, thus ensuring the continuity of the flow of water at the roof level.

Advantageously, and once installed on roofs with a minimum clearance between the edges of the plant modules 300, said modules provide additional protection to buildings.

There represents a perspective view of a building 500 on which plant modules 100, 200, 300 are installed on facades 51 and 52 as well as on a roof 53, the facades 51 and 52 being covered with metal cladding 511 and 521 , and the roof 53 of steel trays 531.

Plant modules 100, 200 and 300 are held in place by means of permanent magnets 104, 204 and 304 (not shown here, but shown in Figures 1, 3, 4 and 5).

The installation time of plant modules 100, 200 and 300 during their deployment is greatly reduced due to the ease of installation of said modules. Indeed, the maintenance of the plant modules 100, 200 and 300 is carried out without drilling the facades 51, 52 as well as the roof 53 in order to maintain, nor gluing said modules on said facades and said roof.

In order to facilitate the visualization of the arrangement of the plant modules 100 and 200, on the cladding 521 of the facade 52, said modules are represented empty, by their respective 10v and 20v structures, presented in Figures 3 and 4. As a reminder, and due to its design, the plant module 200 is used to be positioned in corners 55 of the building 500 and thus maximize its plant cover.

Furthermore, the shear stress which applies to the permanent magnets 104 and 204 which hold the plant modules 100 and 200 is greatly reduced, in addition to its rubber envelope, by the use of plant modules 100s and 200s which are placed directly on the ground S. Thus, the plant modules 100s and 200s serve as a base, on which plant modules 100m and 200m then rest, themselves held on the metal cladding 511 and 512 by means of permanent magnets 104 and 204.

If the facades 51 and 52 have cladding which is made of wood, advantageously, the permanent magnets 104 and 204, respectively having passages 105 and 205, are screwed onto said cladding so that the plant modules 100 and 200 are then installed. This installation option, simple to implement, also facilitates exterior insulation and greening of buildings whose facades do not have metal cladding, while reducing facade preparation actions and minimizing the air space between the cladding and the plant modules, in comparison with other existing solutions.

There represents an example of installation of two plant modules 100a and 100b on the building 500, a facade 54 of which is covered with metal cladding 541. In this example, the plant modules 100a-b each comprise a structure 10a-b, in which a first thermal insulating plate 12a-b, a substrate 16a-b, a second thermal insulating plate 17a-b are inserted, said structures receiving in plant plants 18a-b, irrigated by means of watering pipes 103a- b drop by drop.

In order to renew the air inside the building 500, it is equipped with an air vent 56, shown in dotted lines on the , and includes an opening 561 which opens at the level of the rear walls 106ea and 106eb of the plant modules 100a and 100b.

The air extracted from the building is then confined in a volume delimited by the metal cladding 541 on one side, by the rear walls 106ea and 106eb on the other side, as well as by a sealed frame 19 located around the perimeter delimited by the contour of the two plant modules 100a and 100b side by side. A gas exchange is then carried out between this volume and the root tissue of the plant plants 18a and 18b by means of the orifice 112, presented in the .

If in one embodiment, the plant module 100 comprises thermal insulating plates such as presented in , and positioned between the wall 106e and the substrate 16, the gas exchange between the volume defined previously and the root tissue of the plant plants 18a and 18b, is made possible by means of the orifices 131 and 151 presented in the .

Advantageously, this gas exchange promotes the sequestration by the root tissue of part of the CO2 released at the building 500 through the air vent 56. Likewise, the air entering through the air vent 56 is partly filtered by means of the plant module 100.

In addition, and in addition to their action of thermal regulation of building facades, the foliage of plant plants 18a and 18b also captures the CO2 present in the surrounding air.

Figures 10 and 11 represent a plant module 400 according to a fourth embodiment.

There represents the plant module 400 which comprises a structure 40 composed of five walls 406a-e, a substrate 46 filling the interior volume of said structure, and in which plant plants 48 are placed or cultivated beforehand, said plants being irrigated with by means of a drip watering hose 403, held on the structure 40 by means of notches 401.

As with the previous embodiments, the drip watering hose 403 has two ends 418 and 419 where there is a quick and waterproof connection system.

The plant module 400 is suitable for use on the facades of concrete buildings, for example by being fixed to them with insulation plugs (not shown here), for the exterior insulation of individual homes. and buildings for example.

There represents structure 40 of plant module 400.

The structure 40 mainly comprises five parts which are preferably glued together: a rear part 413, two sides 414c and 414d, a front part 415 and a part defining a bottom (not visible here).

The structure 40 is of parallelepiped shape, preferably made of fully recyclable extruded polystyrene, with very good thermal resistance, the external volume of which is defined by a length L40, a height H40 and a depth P40. Preferably, the rear part 413, the sides 414c and 414d and the front part 415 respectively have a thickness E413 of 130 mm, a thickness E414 of 50 mm and a thickness E415 of 25 mm.

Sides 414c and 414d have a length L414 of 125 mm.

Advantageously, the structure 40 being made of extruded polystyrene, the substrate as well as the root tissue of the plants 48 are protected from cold and heat, in particular by the front part 415.

Preferably, the length L40 as well as the height H40 of the structure 40 are equal to 500 mm. The depth P40 is equal to 280 mm.

As for structure 10 of plant module 100, these dimensional values are given as an example, and do not present a limit.

In order to assemble structure 40, the five parts are glued together.

Furthermore, the front part 415 comprises at least one through hole 407, preferably of circular shape and of diameter D407, a gutter 402, preferably made of metal, making it possible to recover the rainwater which runs off the surface of the modules 400.

In this example, the front part 415 has sixteen holes 407 whose diameter D407 is equal to 80 mm.

Finally, the bottom of the structure 40 includes at least one drain hole 410 in order to drain the excess water contained in the substrate 46.

There and the represent another embodiment of a plant module 700.

There represents an exploded perspective view of the plant module 700, mainly comprising a structure 70, in which a substrate 76 makes it possible to plant plant plants 78, said substrate being irrigated by means of a watering pipe 703 drip, held on the structure 70 by means of notches 701.

Advantageously, the structure 70 is covered with a covering 77 which will make it possible to personalize the visual appearance of the plant module 700, both for indoor and outdoor use. Preferably, the covering 77 is made of two layers of aluminum, between which there is a central layer of plastic material (for example polyethylene). This “sandwich plate” type assembly also makes it possible to protect the structure 70 from mechanical shock, and therefore to preserve the facades of the buildings on which the plant module 700 is installed for longer.

Preferably the covering 77 is glued to the structure 77.

The plant module 700 can also be positioned on facades comprising metal cladding by means of a hanging system 71, on which a multitude of permanent magnets 704 are magnetically fixed thereto. The hanging system 71 can also be used to fix the plant module 700 at the level of a facade of a building which would include wooden cladding, onto which the magnets 704 have been screwed.

The hanging support 71 is preferably made of galvanized steel and has two hooks 711 and 712 located at the ends of said support. The two hooks 711 and 712 are inverted relative to each other and allow the plant module 700 to be held firmly when it is installed in the hanging support 71.

There represents the structure 70 which comprises five walls 706a-e, preferably made of extruded polystyrene.

In this example, the covering 77 only covers a front wall 706a of the structure 70, which corresponds to the green wall of the plant module 700. In contrast, we define a rear wall 706b of the structure 70 as being the wall located at the opposite the green wall of the plant module 700, and which is attached to the interior or exterior facade of a building. Structure 70 protects the facade of buildings against shocks, bad weather and humidity, in distinction from other processes.

The front wall 706a also includes at least one orifice 707, through which the plant 78 is planted in the substrate 76. The front wall 706a insulates the substrate from extreme temperatures.

In addition, the installation of the hanging support 71, at the level of the rear wall 706b of the structure 70, is visible.

There and the represent another embodiment of a plant module 800 supporting the plant module 700 presented in the and to the .

There represents, the plant module 800, which as previously, comprises a structure 80, preferably in extruded polystyrene, which can be covered with a coating 87, preferably in the same materials as those of the coating 77, said structure collecting a substrate 86 in larger quantity, in which plant plants 88 are planted, in order to create, for example a vegetable garden. The assembly is irrigated by means of a drip watering pipe 803, held on the structure 80 by means of notches 801.

The plant module 800 is a so-called support module, which is for example placed on the ground or on a plurality of supports in order to leave a space between the ground and said module.

Thus, and in this example, the plant module 700, in addition to being fixed on a facade of a building, rests on the plane P , represented in dotted lines on the .

In the plant module 800, an orifice 810, here of rectangular shape, present at the level of the plane P allows the excess water contained in the plant module 700 to flow.

There represents an example of arrangement between the plant module 700 and the support plant module 800. For greater readability, plant modules 700 and 800 are represented without plant plants 76 and 86.

Claims (19)

Plant module (100, 200, 300, 400, 700, 800) to cover all or part of building facades or roofs, installed indoors or outdoors, comprising a structure (10, 20, 30, 40, 70 , 80), comprising walls (106a-e, 206a-g, 306a-e, 406a-e, 706a-e, 806a-f) forming a semi-open support for containing a substrate (16, 26, 36, 46 , 76, 86), and comprising a rear wall (106b, 206b, 206d, 306e, 406b, 706b, 806b) for fixing, characterized in that said module comprises at least one permanent magnet (104, 204, 304, 404, 704, 804), to fix said rear wall on a support surface. Plant module (100, 200, 300, 400, 700, 800) according to claim 1, in which the permanent magnet (104, 204, 304, 404, 704, 804) has a substantially cylindrical shape, and preferably has a passage (105, 205, 305, 405, 705, 805) allowing said magnet to be screwed to the rear wall (106b, 206b, 206d, 306e, 406b, 706b, 806b) of the structure (10, 20, 30, 40, 70, 80), or on a support surface. Plant module (100, 200, 300, 400, 700, 800) according to claim 1 or claim 2, wherein the permanent magnet (104, 204, 304, 404, 704, 804) is covered with a waterproof coating made of rubber. Plant module (100, 200, 300, 400, 700, 800) according to any one of the preceding claims, comprising a drip watering pipe (103, 203, 303, 403, 703, 803) which is held in notches (101, 201, 301, 401, 701, 801) positioned on side walls (106c-d, 206c-d, 306c-d, 406c-d, 706c-d, 806c-d) of said module, said pipe watering hose being provided with a quick coupling system at each of its ends to connect said watering hose to the watering hose of a neighboring module. Plant module (100, 200, 300) according to any one of the preceding claims, in which the structure (10, 20, 30) is manufactured from galvanized steel. Plant module (400, 700, 800) according to any one of claims 1 to 4, in which the structure (40, 70, 80) is manufactured from extruded polystyrene, and the at least one permanent magnet (404, 704, 804 ) is screwed onto the rear wall (406b, 706b, 806b) of the structure (40, 70, 80) of said module. Plant module (100, 200, 300) according to any one of claims 1 to 5, comprising at least one thermal insulating plate (12, 13, 17, 27, 37) preferably made of biosourced material, and being arranged between the substrate (16, 26, 36) and the rear wall (106b, 206b, 306b) of the structure (10, 20, 30), and/or on a surface to be planted on said substrate. Plant module (100) according to claim 5, comprising a first thermal insulating plate (12), in contact with the rear wall (106b) of the structure (10) of said module, said first plate being followed by a second plate of rigid thermal insulator (13), said second plate being juxtaposed with a vapor barrier film (15), said film being in contact with the substrate (16), said substrate being followed by a third plate of thermal insulator (17 ). Plant module (100, 200, 400, 700) according to any one of claims 1 to 4, in which a front wall (106a, 206a, 206c, 406a, 706a) comprises at least one orifice (107, 207, 407, 707) to place at least one plant (18, 28, 48, 78). Plant module (100, 200, 400) according to claim 9, in which the front wall (106a, 206a, 206c, 406a, 706a) comprises a plurality of orifices (107, 207, 407, 707) of different shapes. Plant module (100, 200, 400, 700) according to any one of claims 1 to 4, comprising at least one drain hole (110, 210, 410, 710) arranged on a bottom of the structure (10, 20, 40, 70) to evacuate excess water present in the substrate (16, 26, 46, 76). Plant module (100) according to any one of claims 1 to 5, in which the rear wall (106b) comprises at least one orifice (112) allowing air circulation. Plant module (100) according to claim 12, comprising a sealed frame (19) forcing the air entering and leaving a building to circulate through the substrate (16). Plant module (300) according to any one of claims 1 to 5 intended to cover a roof, in a substantially horizontal position relative to the roof, the structure (30) of said module comprising at least one flow channel (302) on the rear wall (306b) of said module, said channel draining the excess water present in the substrate (36). Plant module (200) according to any one of claims 1 to 5, in which the structure (20) has an angle (α), the value of which corresponds to that of corners of buildings, in order to position said module in said corners and thus maximizing the vegetation cover of buildings. Plant module (700, 800) according to claim 6, the structure (70, 80) of which comprises an anti-shock coating (77, 87). Plant module (700) according to claim 6, the structure (70) of which comprises at least one hanging support (71) on which at least two permanent magnets (704) are magnetically fixed. Plant module (800) according to claim 6, said module being intended to be placed on a ground, and whose structure (80) serves as a support for a module located above the plant module (800). Building (500), covered at least partially with a set of plant modules (100, 200, 300, 400, 700, 800) according to one of claims 1 to 18.